Capacitor charger with a modulated current varying with an input voltage and method thereof

ABSTRACT

In a capacitor charger including a transformer having a primary winding connected with an input voltage and a secondary winding for transforming a primary current flowing through the primary winding to a secondary current flowing through the secondary winding, the primary current is adjusted according to a monitoring voltage varying with the input voltage, thereby prolonging the lifetime of the battery that provides the input voltage and improving the power efficiency of the battery.

RELATED APPLICATIONS

This application is a Divisional patent application of co-pending application Ser. No. 11/017,906, filed on 22 Dec. 2004. The entire disclosure of the prior application Ser. No. 11/017,906, from which an oath or declaration is supplied, is considered a part of the disclosure of the accompanying Divisional application and is hereby incorporated by reference.

FIELD OF THE INVENTION

The present invention is related generally to a capacitor charger, and more particularly, to a modulation apparatus and method for the charging current in a capacitor charger varying with the input voltage of the capacitor charger.

BACKGROUND OF THE INVENTION

Portable apparatus is more and more popular, and therefore capacitor charger it uses receives more attentions than ever. Furthermore, battery is typically used for the capacitor charger, since it is the portable apparatus to employ the capacitor charger. Unfortunately, there are disadvantages to a battery serving as a power source. FIG. 1 is an illustrative diagram of a battery 102 providing a voltage V_(bat) and a current I to a load 104. Internally, the battery 102 includes a equivalent resistor R_(S) and a voltage source V_(B), and the voltage V_(bat) it provides equals to the source voltage V_(B) subtracting the voltage drop across the internal resistor R_(S) as

V _(bat) =V _(B) −I×R _(S).  [EQ-1]

FIG. 2 shows an I-V curve of the battery 102 for the voltage V_(bat) and the current I it supplies, in which the vertical axis represents the supplied voltage V_(bat), and the horizontal axis represents the loading current I. From the equation EQ-1, the voltage V_(bat) varies with the current I, as shown by the I-V curve in FIG. 2, the more the current I is drawn by the load 104, the lower the voltage V_(bat) is provided by the battery 102. When the voltage V_(bat) becomes lower, the load 104 intends to draw more current I from the battery 102, and it will have the voltage V_(bat) to be further lower, thereby lowering the power efficiency and shortening the lifetime of the battery 102. When a battery is used to provide the power for a capacitor charger, the battery cannot provide satisfied efficiency and lifetime.

Therefore, it is desired a modulation apparatus and method for a capacitor charger to improve the power efficiency and prolong the lifetime of the battery the capacitor charger uses.

SUMMARY OF THE INVENTION

One object of the present invention is to provide a capacitor charger and the modulation method thereof whose charging current varies with the input voltage, especially supplied by a battery.

Another object of the present invention is to provide a capacitor charger and the modulation method thereof that could improve the power efficiency and prolong the lifetime of the battery the capacitor charger uses.

In a capacitor charger connected with an input voltage, according to the present invention, a transformer transforms a primary current flowing through its primary winding to a secondary current flowing through its secondary winding under the control of a current control circuit for modulating the primary current, and a current set circuit is connected to the current control circuit to adjust the primary current according to a monitoring voltage varying with the input voltage.

Since the monitoring voltage is generated depending on the input voltage, the current set circuit could monitor the variation of the input voltage from the monitoring voltage, and therefore, to have the current set circuit to adjust the primary current when the input voltage is varied or lower than a threshold, thereby improving the power efficiency and prolonging the lifetime of the battery that provides the input voltage.

BRIEF DESCRIPTION OF DRAWINGS

These and other objects, features and advantages of the present invention will become apparent to those skilled in the art upon consideration of the following description of the preferred embodiments of the present invention taken in conjunction with the accompanying drawings, in which:

FIG. 1 is an illustrative diagram of a battery providing a voltage and a current to a load;

FIG. 2 shows an I-V curve of the battery in FIG. 1 for the voltage and the current it supplies;

FIG. 3 shows one embodiment of the present invention in an application for a flash lamp module;

FIG. 4A shows the typical primary current I_(P) of the capacitor charger 200 when using the alkaline battery and lithium battery listed in Table 1;

FIG. 4B shows the two-state switch for the primary current of the capacitor charger 200 in FIG. 3;

FIG. 5 shows one embodiment for the current control circuit 212 in the capacitor charger 200 of FIG. 3;

FIG. 6 shows another embodiment of the present invention in an application for a flash lamp module;

FIG. 7 shows a further embodiment of the present invention in an application for a flash lamp module;

FIG. 8A shows an I-V curve of the capacitor charger 400 in FIG. 7 for its primary current I_(P) and the battery voltage V_(bat); and

FIG. 8B shows the relationship of the on-time period T_(on) for the transistor 21216 in the capacitor charger 400 and the battery voltage V_(bat).

DETAILED DESCRIPTION OF THE INVENTION

The cut-off voltages of alkaline battery and lithium battery under various loading currents are provided in Table 1, where the cut-off voltage is referred to the minimum of the internal source voltage V_(B) in the battery.

TABLE 1 Set No Load Load 0.5 A Load 1 A Cut-Off Cut-Off Cut-Off Battery Internal Voltage, Voltage, Voltage, Type Resistance V_(bat) = 2 V V_(bat) = 2 V V_(bat) = 2 V 2 Cell 0.6Ω 2 V 2.3 V 2.6 V Alkaline 1 Cell 0.2Ω 3 V 3.1 V 3.2 V Li Ion From Table 1, it is shown that, when the loading current is higher, the cut-off voltage is also higher. Therefore, lowering the loading current to follow the lowering of the battery voltage could use the power of the battery more efficiently.

FIG. 3 shows one embodiment of the present invention in an application for a flash lamp module. A capacitor charger 200 comprises a voltage divider 202 composed of resistors R₁ and R₂ connected in series between a battery voltage V_(bat) and ground GND to divide the battery voltage V_(bat) to generate a monitoring voltage V_(D) varying with the battery voltage V_(bat) derived from a node 2022 between the resistors R₁ and R₂, a transformer 204 having its primary winding L₁ connected to the battery voltage V_(bat) and its secondary winding L₂ connected to a flash lamp module 208 through a diode 206, a capacitor 210 shunt to the flash lamp module 208 to be charged and to supply power for the flash lamp module 208, a current control circuit 212 connected to the primary winding L₁ to control the primary current I_(P), a resistor R_(C1) connected between the current control circuit 212 and ground GND, another resistor R_(C2) connected between the current control circuit 212 and a current set circuit 214 through a node 213 between the resistors R_(C1) and R_(C2). The current control circuit 212 and current set circuit 214 may be integrated in a controller chip for the capacitor charger 200. A typical power converter circuit may be used in the current control circuit 212 with an additional current set pin to connect to the node 213. The current set circuit 214 includes a comparator 2142 having two inputs connected with the monitoring voltage V_(D) from the voltage divider 202 and a threshold V_(th), respectively, to generate a comparison signal to switch a transistor 2144, so as to switch the state of the current set pin.

According to the present invention, the capacitor charger 200 could improve the power efficiency and prolong the lifetime of the battery that provides the input voltage V_(bat) of the capacitor charger 200 by modulating the primary current I_(P) according to the battery voltage V_(bat). In this embodiment, two-state switch is designed to illustrate the principles of the present invention, i.e., the state of the current set pin is switched by the transistor 2144 depending on the monitoring voltage V_(D) varying with the input voltage V_(bat). FIG. 4A shows the typical primary current I_(P) of the capacitor charger 200 when using the alkaline battery and lithium battery listed in Table 1, in which curve 216 represents the primary current IP₁ provided by lithium battery, and curve 218 represents the primary current IP₂ provided by alkaline battery. FIG. 4B shows the two-state switch for the primary current I_(P) of the capacitor charger 200 in FIG. 3. In particular, under the use of lithium battery, when the battery voltage V_(bat) supplied for the capacitor charger 200 is high enough, the lithium battery provides the typical primary current IP₁ as it usually does. While the battery voltage V_(bat) drops lower than a threshold V_(bat)′, the capacitor charger 200 will automatically switches its primary current I_(P) to a lower one, for example IP₂, by switching the transistor 2144 of the current set circuit 214 in response to the monitoring voltage V_(D) varying with the battery voltage V_(bat). Due to the switching to the lower loading current, the power efficiency of the lithium battery is improved, and the lifetime thereof is prolonged.

FIG. 5 shows one embodiment for the current control circuit 212 in the capacitor charger 200 of FIG. 3, which includes resistors R₃ and R₄ connected in series between the input voltage V_(bat) and ground to divide the input voltage V_(bat) to generate a voltage V_(D2), and an operational amplifier 21202 having its non-inverting input connected with the voltage V_(D2), its inverting input connected to a node 21203, and its output connected to the gate of a transistor 21204 that has its source connected to the node 21203. Due to the virtual ground between the inputs of the operational amplifier 21202, the node 21203 has the same voltage V_(D2) thereon, and therefore a current I_(A) is generated on the drain of the transistor 21204 to serve as the reference current for a current mirror 21206 to mirror therefrom to generate a mirror current I_(B) supplied to a charge/discharge circuit 21208 to further generate a charged voltage V_(C). A comparator 21210 compares the voltage V_(C) with a reference V_(tf) to generate a comparison signal for control logics 21212 to generate a control signal through a driver 21214 to modulate the on-time period of a transistor 21216 connected in series to the primary winding L₁ of the transformer 204, thereby determining the primary current I_(P) flowing through the primary winding L₁. In this embodiment, the primary current I_(P) also depends on the voltage across the resistor R₅ that could be adjusted by use of the equivalent resistance connected to the node 213, and therefore, the primary current I_(P) could be adjusted by turning on and turning off the transistor 2144. Theoretically, the combination of the operational amplifier 21202, the transistor 21204 and the resistor R₅ is identical to a current source to provide the reference current I_(A) dependent of the voltage V_(D2) and the resistance between the node 213 and ground GND. As illustrated by FIG. 3 and FIG. 4B, together with FIG. 5, when the battery voltage V_(bat) is at a higher level, the transistor 2144 is turned off, and the equivalent resistance between the node 21203 and ground GND is the summation of those of the resistors R₅ and R_(C1). When the battery voltage V_(bat) drops to a lower level to result in the monitoring voltage V_(D) lower than the threshold V_(th), the transistor 2144 is turned on, and the resistor R_(C2) is subsequently shunt to the resistor R_(C1) to lower the equivalent resistance between the node 21203 and ground GND, which will result in a higher reference current I_(A) and subsequently shorten the on-time period T_(on) for the switch 21216 due to shorter charging time for the voltage V_(C) generated by the charge/discharge circuit 21208 to reach a sufficient level, so as to switch the primary current I_(P) from the higher one I_(P1) to the lower one I_(P2).

Referring to FIGS. 3, 4A and 4B, by exemplarily using alkaline battery and lithium battery, the primary current I_(P) is switched based on the curves 216 and 218 shown in FIG. 4A, i.e., the primary current I_(P) will be I_(P1) when using lithium battery, and will be I_(P2) when using alkaline battery. In the beginning, the capacitor charger 200 is assumed to use lithium battery, and therefore the primary current I_(P) is determined to be I_(P1), unless or until the battery voltage V_(bat) is lower than the threshold V_(bat)′ so as for the monitoring voltage V_(D) on the output of the voltage divider 202 is lower than the threshold V_(th), which will have the comparator 2142 to turn on the transistor 2144 to switch the primary current I_(P) from I_(P1) to I_(P2), as shown in FIG. 4B. As a result, the power efficiency of the battery is improved, and the lifetime of the battery is prolonged.

FIG. 6 shows another embodiment of the present invention in an application for a flash lamp module. In a capacitor charger 300, the architecture of the capacitor charger 200 shown in FIG. 3 is employed likewise, and the same numerals for those corresponding elements are also designated hereto, while a voltage selection circuit 302 provides the monitoring voltage V_(D) to the current set circuit 214 for the comparator 2142 to compare with the threshold V_(th) to generate a comparison signal to switch the transistor 2144. When the battery voltage V_(bat) is lower than a threshold V_(bat)′, the voltage selection circuit 302 switches the monitoring voltage V_(D) from one setting value to another, and thus the comparator 2142 in the current set circuit 214 may switch the transistor 2144 from one state to another, thereby changing the equivalent resistance connected to the node 213 and subsequently lowering the level of the primary current I_(P). If the current control circuit 212 and current set circuit 214 are integrated in a controller chip, the chip has a battery type pin connected with the monitoring voltage V_(D), and the voltage selection circuit 302 may determine the monitoring voltage V_(D) according to the type of battery that provides the input voltage V_(bat).

FIG. 7 shows a further embodiment of the present invention in an application for a flash lamp module. In a capacitor charger 400, the architecture of the capacitor charger 300 shown in FIG. 6 is employed likewise, and the same numerals for those corresponding elements are also designated hereto, while a maximum switch on-time setting circuit 402 is additionally comprised in the controller chip to set the maximum of the on-time period T_(on,max) to switch the primary current I_(P), for example by the transistor 21216 in the current control circuit 212 shown in FIG. 5.

FIG. 8A shows an I-V curve of the capacitor charger 400 for its primary current I_(P) and the battery voltage V_(bat), and FIG. 8B shows the relationship of the on-time period T_(on) for the transistor 21216 in the capacitor charger 400 and the battery voltage V_(bat). When the battery voltage V_(bat) gradually drops, the capacitor charger 400 will increase the on-time period T_(on) for the transistor 21216 to maintain the primary current I_(P) stable, until the battery voltage V_(bat) touches down to a threshold V_(bat)″, the on-time period T_(on) reaches the maximum on-time period T_(on,max) set by the maximum switch on-time setting circuit 402. The variation of the primary current I_(P) could be determined by

$\begin{matrix} {{\Delta \; I_{p}} = \frac{V_{bat} \times T_{on}}{L_{1}}} & \left\lbrack {{EQ}\text{-}2} \right\rbrack \end{matrix}$

As shown in FIG. 8B, when the battery voltage V_(bat) drops down to touch the threshold V_(bat)″, the on-time period T_(on) reaches the maximum on-time period T_(on,max). After the battery voltage V_(bat) is lower than the threshold V_(bat)″, the on-time period T_(on) is maintained at the maximum on-time period T_(on,max), and from the equation EQ-2, the variation ΔI_(P) of the primary current I_(P) is proportional to the battery voltage V_(bat), due to the constant on-time period T_(on) and inductance L₁. Therefore, when the battery voltage V_(bat) is lower than the threshold V_(bat)″, the primary current I_(P) of the capacitor charger 400 will decrease in follow to the battery voltage V_(bat), as shown in FIG. 8A, and the lifetime of the battery is prolonged.

While the present invention has been described in conjunction with preferred embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, it is intended to embrace all such alternatives, modifications and variations that fall within the spirit and scope thereof as set forth in the appended claims. 

1. A capacitor charger connected with an input voltage, comprising: a battery power source supplying the input voltage, the battery source being formed by one of a first battery type having a first battery voltage and a second battery type having a second battery voltage, the first battery voltage being greater than the second battery voltage; a transformer having a primary winding connected with the input voltage and a secondary winding for transforming a primary current flowing through the primary winding to a secondary current flowing through the secondary winding; a current control circuit for controlling a magnitude of the primary current; and a current set circuit connected to the current control circuit for setting the magnitude of the primary current responsive to the battery type forming the battery power source, the current set circuit comparing a monitoring voltage corresponding to the input voltage with a threshold value to distinguish the first battery voltage from the second battery voltage, the magnitude of the primary current being reduced responsive to the second battery voltage being detected. 